Inverse kinematic at acceleration level using neural network

Author

Ramdane-Cherif, Amar ; Perdereau, Vkronique ; Drouin, Michel

Author_Institution

Lab. PARC, Univ. Pierre et Marie Curie, Paris, France

Volume

5

fYear

1995

fDate

Nov/Dec 1995

Firstpage

2370

Abstract

The inverse kinematic of a constrained redundant robot manipulator is considered. An optimization procedure using neural network is formulated. It produces position, velocity and acceleration trajectories in joint space from position and orientation trajectories in Cartesian space and guarantees a good tracking of the desired end-effector trajectory. The redundancy is solved by minimizing a performance function. This new method gives an accurate solution with only a few iterations. The application of this scheme to a 3 degrees-of-freedom redundant manipulator is demonstrated through simulation results

Keywords

acceleration control; manipulator kinematics; neural nets; optimisation; position control; redundancy; tracking; 3-DOF manipulator; Cartesian space; acceleration level; constrained redundant robot; inverse kinematics; neural network; optimization; orientation trajectory; performance function; position trajectory; redundancy; tracking; Acceleration; Closed-form solution; Jacobian matrices; Manipulators; Neural networks; Optimal control; Orbital robotics; Robot control; Robot kinematics; Trajectory;

fLanguage

English

Publisher

ieee

Conference_Titel

Neural Networks, 1995. Proceedings., IEEE International Conference on

Conference_Location

Perth, WA

Print_ISBN

0-7803-2768-3

Type

conf

DOI

10.1109/ICNN.1995.487732

Filename

487732